Thermodynamic Model for Predicting Liquid Water− Hydrate

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Ind. Eng. Chem. Res. 2008, 47, 1346-1350

RESEARCH NOTES Thermodynamic Model for Predicting Liquid Water-Hydrate Equilibrium of the Water-Hydrocarbon System Amir H. Mohammadi and Dominique Richon* Mines Paris / ParisTech, CEP-TEP, CNRS FRE 2861, 35 Rue Saint Honore´ , 77305 Fontainebleau, France

With the objective of estimating the solubility of a pure hydrocarbon hydrate former in pure water in equilibrium with gas hydrates, a simple thermodynamic model has been developed, based on the equality of water fugacity in the liquid water and hydrate phases. The solid solution theory of van der Waals-Platteeuw has been applied to calculate the fugacity of water in the hydrate phase. The Henry’s law approach and the activity coefficient method have been used to calculate the fugacities of the hydrocarbon hydrate former and water in the liquid water phase, respectively. The results of this model are compared with some selected experimental data from the literature. Acceptable agreements between the model predictions and experimental data demonstrate the reliability of the model developed in this work. Finally, the possible errors sources in model predictions are discussed. 1. Introduction Gas hydrates are icelike structures in which water molecules, under pressure, form structures composed of polyhedral cages that are surrounding gas molecule “guests” such as methane and ethane.1 The most common gas hydrate structures are those of structure I (sI) and structure II (sII), where each structure is composed of a certain number of large and small cavities formed by water molecules.1 For a molecule to enter a cavity, its size should be smaller than a certain value. Large molecule guests, which can enter only a limited number of large cavities, require smaller “help gas” molecules to mainly fill some smaller cavities sufficiently to stabilize hydrate crystals.1 It has been proved that gas hydrates occur in staggering abundance in cold subsea, sea floor, and permafrost environments, where the temperature and pressure conditions ensure their stability. The natural gas trapped in these deposits represents a potential source of energy many times greater than that of all known classical natural gas reserves.1 Gas hydrates can also form in undersea piping and above-ground pipelines, where they pose a major (and expensive) problem for the petroleum industry.1 On the other hand, hydrate technology has been proposed as a means for CO2 separation from industrial flue gases and sequestration in the deep ocean for reducing the emission of greenhouse gases.1,2 Hydrates are also being regarded as an alternate means of gas transportation and storage.1 It is believed that the potential storage of gas in hydrate form is comparable to the storage of gas in the form of liquefied natural gas (LNG) and compressed natural gas (CNG).3 Knowledge of the liquid water-hydrate (LW-H) equilibrium is necessary in the design of gas transportation and storage process, and the equilibrium should be destined for proposed CO2 sequestration schemes.1,3 These factors, and the potential widespread abundance of gas hydrates in the cold subsea, sea * To whom correspondence should be addressed. Tel.: +(33) 1 64 69 49 65. Fax: +(33) 1 64 69 49 68. E-mail address: [email protected].

floor, and permafrost environments,1-3 warrant an understanding of the LW-H equilibrium. Figure 1 shows a typical solubility-temperature (x-T) diagram for a water-pure hydrate former (limiting reactant) system. As can be seen, the temperature and pressure dependencies of the pure hydrate former solubility in pure water, when in the liquid water-vapor (LW-V) equilibrium region, are different from the corresponding dependency in the LW-H equilibrium region. The LW-V equilibrium is a strong function of temperature and pressure, whereas the LW-H equilibrium is a strong function of temperature but a very weak function of pressure.1,3-12 On the other hand, the pure hydrate former solubility in pure water, when in the LW-V equilibrium region, increases as the temperature decreases at a given pressure, while the corresponding solubility in pure water being in the LW-H equilibrium region decreases as the temperature decreases at the same pressure.1,3-12 Furthermore, the metastable LW-V equilibrium may extend into the gas hydrate formation zone.1,3-12 The experimental works done to describe the LW-H equilibrium are limited, mainly because of two factors: the possible extension of the metastable LW-V equilibrium into the gas hydrate formation region and the experimental restraint that the existing analysis methods require modifications.1,3-8 Literature surveys reveal the availability of few sets of experimental data for the LW-H equilibrium.4-8 Consequently, few reliable models are available in the literature for calculating the LW-H equilibrium.3-5,8-12 However, these models require considerable efforts to fit experimental data. The objective of this work is to develop a simple model based on the equality of water fugacity in the liquid water and hydrate phases for determining the solubility of a pure hydrocarbon hydrate former in pure water, when in equilibrium with gas hydrates. The fugacity of water in the hydrate phase is calculated using the solid solution theory of van der Waals and Platteeuw.13 The hydrocarbon hydrate former fugacity and water fugacity in the liquid water phase are calculated using the Henry’s law

10.1021/ie0709640 CCC: $40.75 © 2008 American Chemical Society Published on Web 01/30/2008

Ind. Eng. Chem. Res., Vol. 47, No. 4, 2008 1347

Figure 1. Typical solubility-temperature (x-T) diagram for the water-single (pure) hydrate former (limiting reactant) system. Legend: LW, liquid water; H, hydrate; V, vapor; and P, pressure. Bold solid lines denote the LW-H equilibrium, solid lines denote the LW-V equilibrium; dashed lines denote the metastable LW-V equilibrium, and bold dashed line denotes the LW-V-H equilibrium.

approach and the activity coefficient method, respectively. The reliability of this model is investigated for methane and ethane by comparing its predictions with selected experimental data from the literature. It is shown that the results are in acceptable agreement, which demonstrates the capability of the model developed in this work for estimating the solubility of a pure hydrocarbon hydrate former in pure water, when in equilibrium with gas hydrates. 2. Liquid Water-Hydrate Equilibrium The LW-H equilibrium of a system is calculated by equating the fugacities of water in the liquid water phase (f Lw) and in the hydrate phase (f Hw):1

f Lw ) f Hw

(1)

The fugacity of water in the hydrate phase (f Hw) is related to the chemical potential difference of water in the filled and empty hydrate cage by the following expression:1

f Hw ) f MT w exp

(

µHw

RT

)

µMT w

(2)

where f MT w is the fugacity of water in the hypothetical empty hydrate phase, and the term µHw - µMT w represents the chemical potential difference of water in the filled (µHw) and empty (µMT w ) hydrate. R represents the universal gas constant. The solid-solution theory of van der Waals and Platteeuw13 1 can be applied to calculate (µHw - µMT w )/RT:

µHw - µMT w RT

)-

∑i V′i ln(1 + ∑j Cij fj) ) ∑i ln(1 + ∑j Cij fj)-V ′ i

(3)

where V′i is the number of cavities of type i per water molecule in a unit hydrate cell,1 Cij represents the Langmuir constant for

the interaction of the hydrocarbon hydrate former with each type cavity, and fj is the fugacity of the hydrate former. The fugacity of water in the empty lattice can be expressed as1 MT MT f MT w ) Pw φw exp

∫PP

MT w

V MT w dP RT

(4)

MT MT where P MT w , φw , Vw , and P are the vapor pressure of the empty hydrate lattice, the correction for the deviation of the saturated vapor of the pure (hypothetical) lattice from ideal behavior, the partial molar volume of water in the empty hydrate1,14 and pressure, respectively. The exponential term is a Poynting-type correction. Equation 4 may be simplified by two assumptions: (1) assuming that the hydrate partial molar volume is equal to the molar volume and is independent of pressure and (2) assuming -3 MPa), so that that P MT w is relatively small (on the order of 10 MT 1 1 φw ) 1. Therefore,

MT f MT w ) Pw × exp

(

)

MT V MT w (P - Pw ) RT

(5)

Using the aforementioned expressions, the following equation is obtained for the fugacity of water in the hydrate phase:

[

f Hw ) PMT w exp

]

MT VMT w (P - Pw ) × [(1 + Csmall f LHC)-V′small × RT ′ ] (6) (1 + Clarge f LHC)-Vlarge

where f LHC is the fugacity of the hydrocarbon hydrate former in the liquid-water phase. The Poynting correction term can be ignored up to intermediate pressures; therefore, the following equation can be obtained to calculate the fugacity of water in the hydrate phase: L -V′small f Hw ) P MT × (1 + Clarge f LHC)- V′large] w × [(1 + Csmall f HC)

(7)

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Ind. Eng. Chem. Res., Vol. 47, No. 4, 2008

The fugacity of water in the liquid water phase can be expressed by15

V′small )

1 23

(14a)

fwL ) xLwγLwPsat w

V′large )

3 23

(14b)

(8)

where xLw and γLw are the water mole fraction and the activity coefficient of water in liquid water phase, when in equilibrium with gas hydrates, respectively. In the intermediate pressure range, the liquid water is an incompressible fluid and the hydrocarbon hydrate former solubility is very small, in comparison to unity, and the activity coefficient of water can be approximated to unity15 (however, one must be careful, because it is not the same as the case at high pressures,15 where the nonideality of the liquid-water phase and solubility become important). Therefore, eq 8 can be satisfactorily written as below:

f Lw = P sat w

(9)

Using eqs 7 and 9, the following expression is obtained:

Psat w

)

PMT w

× [(1 +

′ Csmall f LHC)-V small

Csmall )

×

′ ] (10) (1 + Clarge f LHC)-Vlarge

( ) PMT w Psat w

× [(1 + Csmall f LHC)-V′small × ′ ] ) 0 (11) (1 + Clarge f LHC)-Vlarge

where the fugacity of the hydrocarbon hydrate former in the liquid-water phase up to intermediate pressures can be calculated using the following equation:15

fLHC ) xLHCH′HC-w

(12)

where H′HC-w represents Henry’s constant for hydrocarbon hydrate former-water system. Therefore, the following final expression is obtained for estimating the solubility of a pure hydrocarbon hydrate former in liquid-water phase, when in equilibrium with gas hydrates:

1-

( ) PMT w Psat w

a b exp T T

()

(15)

For tetrakaidecahedra (large cavity):

Clarge )

or

1-

The Langmuir constants (they are generally functions of temperature, pressure, composition, and hydrate structure, whereas the effect of pressure is normally ignored16), which account for the interaction between the hydrate former and water molecules in the cavities, were reported by Parrish and Prausnitz17 for a range of temperatures and hydrate formers. However, the integration procedure was already followed in obtaining the Langmuir constants for wider temperature ranges, using the Kihara18 potential function with a spherical core, according to the study by McKoy and Sinanogˆlu.19 In this work, the Langmuir constants for the interaction of the hydrate former with each type of cavity have been determined using the equations of Parrish and Prausnitz:17 For pentagonal dodecahedra (small cavity):

d c exp T T

()

(16)

where T is in Kelvin and C has units of MPa-1. Constants a-d are reported in Table 1. The concept of having a universal empty hydrate vapor pressure for each structuresprompted Dharmawardhana et al.20 to calculate the PMT w value from several simple hydrate threephase ice-vapor-hydrate equilibria. By equating the fugacity of water in the hydrate phase to that of pure ice at the threephase line, Dharmawardhana et al.20 obtained the following equation for the vapor pressure of the empty hydrate structureI:1

(

PMT w ) 0.1 exp 17.440 -

6003.9 T

)

-1 and T is in Kelvin. where PMT w is given in units of MPa The following values for Henry’s constant of the hydrocarbon hydrate former-water system can be used:21

H′HC-w ) (10A+B/T+Ch ×log(T)+D×T) × 0.1 × [(1 + CsmallxLHCH′HC-w)-V′small × ′ ] ) 0 (13) (1 + ClargexLHCH′HC-w)-Vlarge

Our model, which has led to eq 13, allows easy calculation of the solubility of a pure hydrocarbon hydrate former in the liquid water, when in equilibrium with gas hydrates. Its main advantages are (i) the availability of necessary input data and (ii) the simplicity of the calculations, because the calculations can be done using Microsoft Excel spreadsheets. Furthermore, as can be observed in eq 13, almost all terms are temperaturedependent, which indicates that the solubility of a pure hydrocarbon hydrate former in liquid-water phase, when in equilibrium with gas hydrates, is a strong function of temperature and only a weak function of pressure. 2.1. Model Parameters. In eq 13, the following values of V′i for structure-I hydrates can be used:1

(17)

(18)

where T is in Kelvin and H′HC-w is given in units of MPa. The constants A, B, C h , and D are given in Table 2. 3. Results and Discussion Among the LW-H equilibrium data reported in the literature for the hydrocarbon + water systems, those reported by Servio and Englezos7 and Kim et al.8 for methane solubility in pure water being in equilibrium with gas hydrates seem to be the most reliable. They are reported in Tables 3a and 3b, respectively. As can be seen, the temperature range is 274.15-281.7 K, and the pressures go up to 14.4 MPa. The experimental data of Yang et al.5 for methane solubility in pure water, when in equilibrium with gas hydrates, have not been considered in this work, because they are not consistent with other literature data.7,8 Tables 3a and 3b also show the predictions of the model developed in this work and the absolute deviations (ADs). As can be seen, eq 13 (without any adjustable parameter) shows

Ind. Eng. Chem. Res., Vol. 47, No. 4, 2008 1349 Table 1. Constants a-d Used in eqs 15 and 16a hydrate former

a (K MPa-1)

b (K)

c (K MPa-1)

d (K)

methane ethane

0.0037237 0

2708.8 0

0.018373 0.006906

2737.9 3631.6

a

Data taken from ref 17.

Table 2. Constants A-D Used in eq 18a hydrocarbon methane ethane a

A

B

C h

D

Tmin (K) Tmax (K)

147.788 -5768.3 -52.2952 0.018616 273.15 146.901 -5768.3 -51.8593 0.017410 273.15

373.15 343.15

Data taken from ref 21.

Table 3. Experimental and Predicted Solubility of Methane in Pure Water Being in Equilibrium with Gas Hydrates (Liquid Water-Hydrate Equilibrium) temperature, T (K)

pressure, P (MPa)

Methane Solubility experimental

predicted

AD%a

Englezos7

(a) Using Experimental Data from Servio and 274.35 3.5 1.170 × 10-3 1.260 × 10-3 275.45 3.5 1.203 × 10-3 1.340 × 10-3 1.250 × 10-3 274.15 5.0 1.190 × 10-3 277.35 5.0 1.360 × 10-3 1.500 × 10-3 275.25 6.5 1.201 × 10-3 1.330 × 10-3 280.15 6.5 1.567 × 10-3 1.770 × 10-3 276.2 277.9 279.9 280.5 276.4 278.7 280.1 280.7 276.7 278.9 280.4 281.1 276.9 279.2 280.6 281.7 a

(b) Using Experimental Data from Kim et al.8 5 1.33 × 10-3 1.40 × 10-3 5.1 1.59 × 10-3 1.55 × 10-3 5.1 1.75 × 10-3 1.75 × 10-3 5.1 1.86 × 10-3 1.81 × 10-3 1.41 × 10-3 10.1 1.33 × 10-3 10.2 1.59 × 10-3 1.42 × 10-3 10.2 1.75 × 10-3 1.77 × 10-3 10.2 1.86 × 10-3 1.84 × 10-3 12.7 1.33 × 10-3 1.45 × 10-3 12.7 1.59 × 10-3 1.65 × 10-3 12.7 1.75 × 10-3 1.80 × 10-3 1.88 × 10-3 12.7 1.86 × 10-3 14.3 1.33 × 10-3 1.46 × 10-3 14.4 1.59 × 10-3 1.68 × 10-3 14.3 1.75 × 10-3 1.82 × 10-3 14.3 1.88 × 10-3 1.94 × 10-3

7.7 11.4 5.0 10.3 10.7 13.0 5.3 2.5 0.0 2.7 6.0 10.7 1.1 1.1 9.0 3.8 2.9 1.1 9.8 5.7 4.0 3.2

AD ) |(experimental value - predicted value)/experimental value|.

Table 4. Experimental and Predicted Solubility of Ethane in Pure Water Being in Equilibrium with Gas Hydrates (Liquid Water-Hydrate Equilibrium) Ethane Solubility

temperature, T (K)b

pressure, P (MPa)

experimentala

predicted

AD%

277.3 277.8 278.5

10.1 15.1 20.1

4.37 × 10-4 4.37 × 10-4 4.37 × 10-4

4.90 × 10-4 5.12 × 10-4 5.43 × 10-4

12.1 17.2 24.3

a Data taken from Kim et al.8 b Experimental gas solubility is not absolutely temperature-dependent; consequently, the corresponding experimental data cannot be considered to be reliable.

encouraging results. The predictions show